Classical ElectrodynamicsProblems after each chapter |
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Page 193
... vector on the left can form scalar or vector products from the left , and correspondingly for the unit vector on the right . Given the dyadic , we can determine the tensor elements by taking the appropriate scalar products : • Tii = εi ...
... vector on the left can form scalar or vector products from the left , and correspondingly for the unit vector on the right . Given the dyadic , we can determine the tensor elements by taking the appropriate scalar products : • Tii = εi ...
Page 283
... vector fields , we expect that a considerable improvement can be made by developing vector equivalents to the Kirchhoff integral ( 9.65 ) . 9.6 Vector Equivalents of Kirchhoff Integral To obtain vector equivalents to the Kirchhoff ...
... vector fields , we expect that a considerable improvement can be made by developing vector equivalents to the Kirchhoff integral ( 9.65 ) . 9.6 Vector Equivalents of Kirchhoff Integral To obtain vector equivalents to the Kirchhoff ...
Page 307
... vector makes an angle a with the normal to the screen . The polarization vector is perpendicular to the plane of incidence . ( a ) Calculate the diffracted fields and the power per unit solid angle transmitted through the opening ...
... vector makes an angle a with the normal to the screen . The polarization vector is perpendicular to the plane of incidence . ( a ) Calculate the diffracted fields and the power per unit solid angle transmitted through the opening ...
Contents
1 | 1 |
BoundaryValue Problems in Electrostatics I | 26 |
Dielectrics | 98 |
Copyright | |
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4-vector acceleration Ampère's law angular distribution approximation atomic axis behavior boundary conditions bremsstrahlung calculation Chapter charge q charged particle Cherenkov radiation classical coefficients collisions component conducting conductor consider constant coordinate cross section cylinder d³x dielectric diffraction dipole direction discussed E₁ electric field electromagnetic fields electron electrostatic emitted energy loss energy transfer equation of motion factor force equation frame frequency given Green's function impact parameter incident particle integral Lagrangian limit Lorentz force Lorentz invariant Lorentz transformation m₁ magnetic field magnetic induction magnitude Maxwell's equations meson modes momentum multipole nonrelativistic obtain orbit oscillations P₁ P₂ parallel perpendicular photon plane plasma polarization power radiated problem quantum quantum-mechanical radius region relativistic result scalar scattering screen shown in Fig shows sin² solid angle solution spectrum sphere spherical surface transverse V₁ vanishes vector potential wave number wavelength ΦΩ